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Abstract:
European freshwater sculpins of the genus Cottus receive attention as a model for
studying the initial steps of a homoploid hybrid speciation. An invasive lineage of Cottus,
which originated from the hybridization between Cottus rhenanus and Cottus perifretum,
was able to invade a new habitat and occupy a new ecological niche not available to its
parent species.
In this thesis several aspects of this process are studied at the transcriptome level. To this
means, a Cottus specific oligonucleotide microarray was designed based on
transcriptome sequencing. The binding behavior of the probes on the microarray was
experimentally determined, revealing large variation in binding behavior between probes.
A newly developed normalization approach was applied, to remove artifacts resulting from
this variation.
As a first step, the phenotypic differentiation between invasive Cottus and its parent
species was assessed. Expression level differentiation indicates that the invasive Cottus
phenotype is overall intermediate between its parent species in agreement with its hybrid
origin. However, invasive Cottus are characterized through a set genes with unique
expression distinguishing it from its parent species. These are mainly genes with
transgressive expression patterns, i.e. expression patterns outside the expression range
observed in the parent species. Genes which are transgressively overexpressed in
invasive Cottus are functionally correlated as evidenced through Gene Ontology term
enrichment. These genes represent candidates for the adaptive phenotypic change which
enabled the colonization of the new habitat by invasive Cottus. Some of the transgressive
expression patterns were already observed in F2 crosses between the parent species,
which were analyzed as a proxy of the initial stages of hybrid speciation. This observation
suggests that initial hybridization played a role in the formation of the unique invasive
phenotype. Importantly, a large fraction of transgressive patterns of over expression were
not observed in the in F2 crosses and thus must have been acquired when invasive
Cottus evolved after the initial hybridization. Overall these results are in line with an
evolutionary process where natural selection acts on hybridization-induced increased
phenotypic diversity to shape the new invasive phenotype, thus leading to ecological and
spatial segregation from the parent species.
As a second aspect, the role of phenotypic plasticity in promoting adaptation and
diversification was assessed. Evolutionary mechanisms involving phenotypic plasticity do
apply particularly in situations involving the adaptation to a new environment. This is the
case for invasive Cottus, which colonized a new habitat with a different thermal regime.
Temperature is a key factor structuring ecological communities along the fluvial
ecosystems inhabited by Cottus. Thus, thermal plasticity was assessed by measuring
temperature specific gene expression profiles over a temperature range from 14°C to
25°C. This temperature range reflects conditions in the originally occupied and the newly
invaded habitat during summer when temperature differences between the two habitats
are most pronounced. Expression profile differentiation between the invasive Cottus and
the parent species was most pronounced at the lower half of the analyzed temperature
range (i.e. < 21°C). This is surprising, given that these temperatures are not an exclusive
property of the newly invaded habitat but are commonly observed both in original and
newly invaded habitats. Comparative analysis of gene expression changes over
temperatures revealed plastic responses shared by all the species of Cottus in analysis as
well as changes in plasticity between parent species and invasive Cottus. In particular the
augmentation of pre-existing plastic responses was shown to contribute to the phenotypic
differentiation of invasive Cottus, which is in line with the prediction that plastic traits
contribute to early steps of adaptive evolution. For the temperatures < 21°C, the
augmentation of a plastic response was found in a mitochondrion related phenotype of
potential adaptive value.
In summary, this thesis provides evidence in support of proposed modes of hybrid
speciation as well as for proposed modes of adaptive evolution through the modification of
plastic phenotypes. Furthermore, this thesis constitutes the first systematic phenotypic
analysis of the Cottus study system and therefore is an important step towards the
identification of the adaptive changes underlying the diversification process.